Transcription of bacteriophage T4 DNA by Escherichia coli RNA polymerase in vitro: identification of some immediate-early and delayed-early genes

Npas4: Linking Neuronal Activity to Memory

Immediate-early genes (IEGs) are rapidly activated after sensory and behavioral experience and are believed to be crucial for converting experience into long-term memory. Neuronal PAS domain protein 4 (Npas4), a recently discovered IEG, has several characteristics that make it likely to be a particularly important molecular link between neuronal activity and memory: it is among the most rapidly induced IEGs, is expressed only in neurons, and is selectively induced by neuronal activity. By orchestrating distinct activity-dependent gene programs in different neuronal populations, Npas4 affects synaptic connections in excitatory and inhibitory neurons, neural circuit plasticity, and memory formation. It may also be involved in circuit homeostasis through negative feedback and psychiatric disorders. We summarize these findings and discuss their implications.

Splitting hares and tortoises: a classification of neuronal immediate early gene transcription based on poised RNA polymerase II

Immediate early transcription is an integral part of the neuronal response to environmental stimulation and serves many brain processes including development, learning, triggers of programmed cell death, and reaction to injury and drugs. Following a stimulus, neurons express a select few genes within a short period of time without undergoing de novo protein translation. Referred to as the 'gateway to genetic response', these immediate early genes (IEGs) are either expressed within a few minutes of stimulation or later within the hour. In neuronal IEGs that are expressed rapidly, productive elongation in response to neuronal activity is jump-started by constitutive transcription initiation together with RNA polymerase II stalling in the vicinity of the promoter. IEGs expressed later in the hour do not depend on this mechanism. On the basis of this Polymerase II poising, we propose that the immediate early genes can be grouped in two distinct classes: the rapid and the delayed IEGs. The possible biological relevance of these classes in neurons is discussed.

Identification of two middle promoters upstream DNA ligase gene 30 of bacteriophage T4

Bacteriophage T4 DNA ligase gene 30 lies in the cluster of prereplicative genes located counterclockwise from map units 149 to 121. Based on the early transcription studies this gene has been considered as a typical early gene of bacteriophage T4. In agreement with this assignment, two strong T4 early promoters, P(E )30.8 (128.6) and P(E )30.7 (128.2), located about 3.1 and 2.7 kb upstream from gene 30 have been revealed by promoter mapping and sequence analysis. In addition, the existence of a putative early promoter just upstream of gene 30 was proposed from the sequence data. However, here we show that the putative early promoter just upstream of gene 30 is, in fact, a T4 middle promoter. Furthermore, we detected one more middle promoter located in the genomic region between early promoter P(E )30.7 (128.2) and DNA ligase gene 30 in the coding region of gene 30.3. Both new middle promoters have differences from the consensus MotA box, while their -10 regions match the sigma(70) consensus sequence very well. The 5' ends of MotA-dependent transcripts directed from these promoters, as well as the kinetics of 5' end accumulation in the cells, have been determined by primer extension analysis. The results of these analyses indicate that both MotA-dependent and MotA-independent promoters control the transcription of T4 DNA ligase gene 30 in vivo. Moreover, we show that the first transcripts for gene 30 are directed from its own middle promoter, P(M)30.

Expression and DNA sequence of the cloned bacteriophage T4 dCMP hydroxymethylase gene

A plasmid expressing the cloned bacteriophage T4 gene 42 gave the same levels of complementation of gene 42 mutants in a polarity-suppressing rho mutant as in a rho+ host. A reading frame likely corresponding to gene 42 and putative promoter and terminator sequences were identified in the partial sequence of the cloned fragment.

Role of the host cell in bacteriophage T4 development. II. Characterization of host mutants that have pleiotropic effects on T4 growth

Mutant host-defective Escherichi coli that fail to propagate bacteriophage T4 and have a pleiotropic effect on T4 development have been isolated and characterized. In phage-infected mutant cells, specific early phage proteins are absent or reduced in amount, phage DNA synthesis is depressed by about 50%, specific structural phage proteins, including some tail and collar components, are deficient or missing, and host-cell lysis is delayed and slow. Almost all phage that can overcome the host block carry mutantions that map in functionally undefined 'nonessential' regions of the T4 genome, most near gene 39. The mutant host strains are temperature sensitive for growth and show simultaneous reversion of the ts phenotype and the inability to propagate T4+. The host mutations are cotransduced with ilv (83 min) and may lie in the gene for transcription termination factor rho.

Participation of bacteriophage T4 gene 41 in replication repair

The location of the non-essential T4 mutant uvs79, with defective replication repair, is described. After crosses with double mutants dispersed over the early region of T4, a linkage was observed with the double mutant am41 : am42. For more accurate location, crosses were made with single mutants. Uvs79 proved to be located between mutants amC23 and amN81 in gene 41, as shown by 3-point crosses. No genetic complementation with respect to multiplicity reactivation was found between amN81 and uvs79 after co-infection of an su- host. Apparently, mutant amN81 is disturbed as to replication repair and, owing to its lack of DNA synthesis, also in replication-dependent recombination repair. Consequently, the product of gene 41 has a function additional to its RNA-primer induction during replication of undamaged DNA. Presumably, the product of gene 41 induces RNA primers opposite DNA regions containing lesions. This capability is believed to be specifically affected by the uvs79 mutation.

Transcription termination factor rho and T-even phage development

A functional factor rho is necessary for T-even phage development; phages T2 and T4 require different degrees of rho activity. The rho inactivation by ts-mutations in E. coli causes a reduction of some early protein synthesis and an early formation of some proteins normally typical of a later stage. Besides, it weakens the synthesis of some late proteins, impairs the capsid proteins maturation and sharply inhibits phage DNA replication in infected cells. However, in the absence of a functional rho all the proteins required for phage DNA synthesis the formed, indicating that this factor is directly involved in the process of T-even phage DNA replication. A number of rifampicin-resistant mutations supressing the rho 15 mutation and restoring the ability of cells to grow at high temperature were isolated. However these RNA polymerase mutations do not or only partially suppress the effect of rho mutations on T-even phage development and the phage DNA synthesis. The role of rho in DNA transcription and replication during bacteriophage development is discussed.

DNA strand specificity of temporal RNA classes produced during infection of Bacillus subtilis by SP82

The DNA of the Bacillus subtilis bacteriophage SP82 has been separated into heavy (H) and light (L) fractions by centrifugation in buoyant density gradients in the presence of polyguanylic acid. Competition-hybridization experiments were performed with these separated fractions using RNAs isolated from cells labeled at intervals which account for 80% of the lytic cycle and unlabeled competitor RNAs isolated from phage-infected cells at 2-min intervals throughout infection. The analysis of temporal RNA classes were facilitated by use of a double reciprocal plot of the data. Five temporal classes binding to the H fraction and three binding to the L fraction were detected; the possible existence of an additional class transcribed from the H fraction is discussed. RNA synthesized in the presence of chloramphenicol contains two of the three classes produced from L-DNA and two of the five classes transcribed from H-DNA.

Thiolutin resistant mutants of Escherichia coli are they RNA chain initiation mutants?

Four mutants of Escherichia coli KL16 resistant to the antibiotic Thiolutin have been isolated. This drug was earlier reported to be an inhibitor of RNA chain elongation. The first mutant, TLrI, is resistant only in rich or partially rich media: it can, however, grow in minimal medium containing the drug with a very long doubling time. The other mutants TLrII, TLrIIIa and TLrIIIb are resistant in rich as well as minimal media. beta-galactosidase could not be induced in TLrI and TLrII in the presence of thiolutin whereas the enzyme is constitutively synthesised in TLrIIIa and TLrIIIb irrespective of the drug. The mutants do not support the development of phage T4 in presence of the drug, if the drug is added along with the phage, but "escape" the inhibition if phage development is allowed to proceed for some time before the addition of the drug. The time of this escape is characteristic of the mutant. Even in a sensitive strain, T7 growth escapes inhibition very soon after infection, around the time the phage-specific RNA polymerase is synthesized. In the parent strain the kinetics of inhibition of beta-galactosidase induction resembles more the inhibition caused by rifampicin than by streptolydigin. It is proposed that thiolutin could be an inhibitor of RNA chain initiation and resistance might be due to mutation in the subunit(s)/factor(s) involved in initiation.

Bacteriophages of Bacillus subtilis

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Regulation of early mRNA synthesis after bacteriophage T4 infection of Escherichia coli

Regulation of T4-specific mRNA synthesis was studied during leucine starvation of a leucine-requiring stringent Escherichia coli B strain. This was done by imposing starvation prior to T4 infection and then letting RNA synthesis proceed for different time periods. Rifampin or streptolydigin was added to stop further RNA synthesis, and protein synthesis was restored by addition of leucine. Samples were withdrawn at different times, and the enzyme-forming capacities found that, during conditions which elicit the stringent response in uninfected bacteria, immediate early mRNA is not stringently regulated. This conclusion contradicts the earlier conclusion of others, obtained by measuring incorporation of radioactive uracil; this is explained by the observation of Edlin and Neuhard (1967), confirmed and extended by us to the T4-infected cell, that the incorporation of uracil into RNA of a stringent strain is virtually blocked by amino acid starvation, whereas that of adenine continues at 30 to 50% of the rate seen in the presence of the required amino acid.

Transcription of bacteriophage T4 genome in vitro. Heterogeneity of RNA polymerase in crude extracts of normal and T4-infected Escherichia coli B

In order to obtain RNA polymerase preparations carrying the necessary specificity determinants to transcribe the delayed-early genes of bacteriophage T4, crude extracts of uninfected and T4-infected Escherichia coli were fractionated in glycerol gradients of low ionic strength. In contrast to the reported sedimentation behavior of the purified enzyme, the RNA polymerase activity in crude extracts of normal and infected cells sedimented heterogeneously over a wide range of sedimentation coefficients. When the "heavy" (24-33 S) and "light" (14-20 S) regions of the gradient were precipitated with ammonium sulfate and recentrifuged, the former split into two subfractions, one again sedimenting heavy and the other sedimenting light. The latter did not split under the same conditions. The resulting subfractions from uninfected cell extracts had different thermal thermal stabilities at 50 degrees (half-lives ranging from 2-3 to 25 min) while those from T4-infected cell extracts were very thermolabile (half-life of 1-2 min). All the subfractions were more active on T4 DNA than on calf-thymus DNA. They also formed rifampicin-resistant, RNA chain initiation complexes with T4 DNA. Based on the kinetics of heat inactivation with T4 and calf thymus DNAs as templates and preferential transcription of T4 DNA, it is proposed that the T4-infected cell enzymes prepared as described here harbor heat-labile initiation factor(s). During infection the heavy sedimenting RNA polymerase activity disappears after 2.5 min at 37 degrees. This appears to require phage-specific protein synthesis because (a) it does not happen in the presence of chloramphenicol and (b) it does not happen in T4 ghost-infected cells.

Transcriptional regulation of T4 bacteriophage-specific enzymes synthesized in vitro

In contrast to dihydrofolate reductase and four other phage-specific enzymes, the initiation of deoxynucleotide kinase is essentially prevented if rifampin is added to a culture of Escherichia coli B cells within 1.5 min after infection with T4. Deoxynucleotide kinase thus belongs to a group of so-called delayed-early enzymes that is not initiated from an immediate-early promoter site. We prepared crude extracts from infected cells in a manner designed to maintain the integrity of the complexes of native, endogenous T4 DNA with bacterial structural and enzymatic units concerned with RNA synthesis. The initiation of the synthesis of the mRNA for dihydrofolate reductase, an example of an immediate-early enzyme, and deoxynucleotide kinase, a special type of delayed-early enzyme, was studied with these extracts prepared from cells infected in the absence or presence of chloramphenicol. Initiation of transcription of the dihydrofolate reductase gene is immediate when programmed by extracts made either from cells treated with chloramphenicol prior to infection (CM extracts) or from cells 3 min into the normal infection cycle (3-min extracts). However, initiation of transcription of the deoxynucleotide kinase gene programmed by CM extracts is delayed 2 min relative to the immediate initiation of transcription of the deoxynucleotide kinase gene programmed by 3-min extracts. These experiments duplicated in vitro effects of the antibiotics on the synthesis of phage-specific mRNA previously noted only in vivo.

Initiation characteristics for the synthesis of five T4 phage-specific messenger RNAs in vitro

The involvement of the nucleoside triphosphates in the initiation of the synthesis of the messenger ribonucleic acid of five T4 specific enzymes has been studied. Only one of these, the messenger RNA for deoxynucleosidemonophosphate kinase, can be initiated in the presence of one nucleoside triphosphate, namely ATP. All of the remaining four require the presence of at least two nucleoside triphosphates during the initiation period. The combination of ATP and UTP was best for the initiation of messenger RNA for dihydrofolate reductase, ATP and CTP for deoxycytidylate hydroxymethyltransferase and beta-glucosyltransferase, and ATP and GTP for alpha-glucosyltransferase. We have concluded that there is a great variation in the nucleotide composition and sequence of the initiation sites in T4 DNA. No correlation in the requirements of nucleoside triphosphates during the initiation period could be observed among the five systems studied according to their classification as one type or another of "early" T4 messenger RNA.

Immediate-early expression of the gene causing superinfection breakdown in bacteriophage T4B

Superinfection breakdown appears to belong to the "immediate-early" functions induced by T4 phage.

SP62, a viable mutant of bacteriophage T4D defective in regulation of phage enzyme synthesis

SP62 is a mutant of bacteriophage T4D that was discovered because it produces fewer phage than the wild type in the presence of 5-fluorodeoxyuridine. In the absence of phage DNA synthesis, SP62 solubilizes host DNA slower than normal; this may explain the sensitivity to 5-fluorodeoxyuridine. In Escherichia coli B at 37 C in the absence of drugs, SP62 makes DNA at a normal rate and the kinetics of appearance of phage are nearly normal. Under the same conditions, SP62 produces T4 lysozyme (gene e) at a normal rate until 20 min, but then produces it at twice the normal rate until at least 60 min. It has long been known that, when T4 DNA synthesis is blocked (DNA(-) state) in an otherwise normal infection, the synthesis of a number of early enzymes continues beyond the shutoff time of about 12 min seen in the DNA(+) state, but still stops at about 20 min. We have termed the 12-min shutoff event S1 and the 20-min shutoff event S2. We show here that, in the DNA(+) state, SP62 makes four early enzymes normally, i.e., S1 occurs. However, in the DNA(-) state (where S1 is missing), SP62 continues to make dCTPase (gene 56), dCMP hydroxymethylase (gene 42), and deoxynucleotide kinase (gene 1) for at least an hour; this results in production of up to 13 times the normal level of dCTPase at 60 min after infection, or 6 times the DNA(-) level. We conclude that SP62 is defective in the second shutoff mechanism, S2, for these three enzymes. In contrast, SP62 causes premature cessation of dTMP synthetase production in the DNA(-) state; the result is a twofold underproduction of dTMP synthetase. Autoradiograms of pulse-labeled proteins separated by slab-gel electrophoresis in the presence of sodium dodecyl sulfate show that a number of other T4 early proteins, including the products of genes 45, 46, and rIIA, are synthesized longer than normal by SP62 in the DNA(-) state. Few late proteins are made in the DNA(-) state, but in autoradiograms examining the DNA(+) state there is little or no effect of the SP62 mutation on the synthesis of T4 late or early proteins. Circumstantial evidence is presented favoring a role for the gene of SP62 in translation of certain mRNAs. At very high temperatures (above 43 C) in the absence of drugs, phage production, but not DNA synthesis, is much reduced in SP62 infections relative to wild-type T4 infections; this temperature sensitivity is greater on E. coli CR63 than on E. coli B. This property has facilitated recognition of the SP62 genotype and aided in complementation testing and genetic mapping. A later publication will provide evidence that SP62 defines a new T4 gene named regA, which maps between genes 43 and 62.

Transcription units in bacteriophage T4

We have investigated the possibility of assigning genes of T4 bacteriophage to their units of transcription (scriptons) by studying gene expression from UV-irradiated DNA templates. Since RNA chains are prematurely terminated on UV-irradiated DNA templates and since the promotor distal part of the RNA chain is deleted, the expression of any gene is inversely proportional to the distance between the promotor and the promotor distal end of the gene. We find that the early genes, 43, 45 and rIIB, are promotor proximal. Since at least genes 43 and rIIB are classified as delayed early genes, these results suggest that their synthesis may require the recognition of new promotors. Additional early genes (44, 62, 42, 46, 47, 55, and rIIA) and some late genes (34, 37, and 38) have also been assigned positions relative to their promotors.

Transforming ability of a T4 RNA-DNA copolymer

A coliphage T4-specific RNA-DNA copolymer is genetically competent to transform a marker in gene 43, the DNA polymerase.